1. AP Biology 2005-2006 Chapter 17. From Gene to Protein

2. AP Biology 2005-2006 1 gene – 1 enzyme hypothesis Beadle & Tatum  Compared mutants of bread mold, Neurospora fungus created mutations by X-ray treatments  X-rays break DNA  inactivate a gene wild type grows on “minimal” media  sugars + required precursor nutrient to synthesize essential amino acids mutants require added amino acids  each type of mutant lacks a certain enzyme needed to produce a certain amino acid  non-functional enzyme = broken gene

3. AP Biology 2005-2006 Beadle & Tatum 1941 | 1958 George Beadle Edward Tatum

4. AP Biology 2005-2006 Beadle & Tatum’s Neurospora experiment

5. AP Biology 2005-2006 proteinRNA The “Central Dogma” DNA transcriptiontranslation replication How do we move information from DNA to proteins?

6. AP Biology 2005-2006 RNA ribose sugar N-bases  uracil instead of thymine  U : A  C : G single stranded mRNA, rRNA, tRNA, siRNA…. RNADNA transcription

7. AP Biology 2005-2006 Transcription Transcribed DNA strand = template strand  untranscribed DNA strand = coding strand Synthesis of complementary RNA strand  transcription bubble Enzyme  RNA polymerase

8. AP Biology 2005-2006 Role of promoter 1. Where to start reading = starting point 2. Which strand to read = template strand 3. Direction on DNA = always reads DNA 3'  5' Transcription in Prokaryotes Initiation  RNA polymerase binds to promoter sequence on DNA

9. AP Biology 2005-2006 Transcription in Prokaryotes Elongation  RNA polymerase unwinds DNA ~20 base pairs at a time  reads DNA 3’  5’  builds RNA 5’  3’ No proofreading 1 error/10 5 bases many copies short life not worth it!

10. AP Biology 2005-2006 Transcription in Prokaryotes Termination  RNA polymerase stops at termination sequence  mRNA leaves nucleus through pores

11. AP Biology 2005-2006 Transcription in Eukaryotes

12. AP Biology 2005-2006 Prokaryote vs. Eukaryote genes Prokaryotes  DNA in cytoplasm  circular chromosome  naked DNA  no introns Eukaryotes  DNA in nucleus  linear chromosomes  DNA wound on histone proteins  introns vs. exons eukaryotic DNA exon = coding (expressed) sequence intron = noncoding (inbetween) sequence

13. AP Biology 2005-2006 Transcription in Eukaryotes 3 RNA polymerase enzymes  RNA polymerase I only transcribes rRNA genes  RNA polymerase I I transcribes genes into mRNA  RNA polymerase I I I only transcribes rRNA genes  each has a specific promoter sequence it recognizes

14. AP Biology 2005-2006 Transcription in Eukaryotes Initiation complex  transcription factors bind to promoter region upstream of gene proteins which bind to DNA & turn on or off transcription TATA box binding site  only then does RNA polymerase bind to DNA

15. AP Biology 2005-2006 A A A A A 3' poly-A tail CH 3 mRNA 5' 5' cap 3' G PPP Post-transcriptional processing Primary transcript  eukaryotic mRNA needs work after transcription Protect mRNA  from RNase enzymes in cytoplasm add 5' cap add polyA tail Edit out introns eukaryotic DNA exon = coding (expressed) sequence intron = noncoding (inbetween) sequence primary mRNA transcript mature mRNA transcript pre-mRNA spliced mRNA 50-250 A’s

16. AP Biology 2005-2006 Transcription to translation Differences between prokaryotes & eukaryotes  time & physical separation between processes  RNA processing

17. AP Biology 2005-2006 Translation in Prokaryotes Transcription & translation are simultaneous in bacteria  DNA is in cytoplasm  no mRNA editing needed

18. AP Biology 2005-2006 mRNA From gene to protein DNA transcription nucleus cytoplasm mRNA leaves nucleus through nuclear pores proteins synthesized by ribosomes using instructions on mRNA a a a a a a aa ribosome protein translation

19. AP Biology 2005-2006 How does mRNA code for proteins? TACGCACATTTACGTACGCGG DNA AUGCGUGUAAAUGCAUGCGCC mRNA Met Arg Val Asn Ala Cys Ala protein ? How can you code for 20 amino acids with only 4 nucleotide bases (A,U,G,C)?

20. AP Biology 2005-2006 Cracking the code Nirenberg & Matthaei  determined 1 st codon–amino acid match UUU coded for phenylalanine  created artificial poly(U) mRNA  added mRNA to test tube of ribosomes, tRNA & amino acids mRNA synthesized single amino acid polypeptide chain 1960 | 1968 phe–phe–phe–phe–phe–phe

21. AP Biology 2005-2006 Marshall NirenbergHeinrich Matthaei

22. AP Biology 2005-2006 Translation Codons  blocks of 3 nucleotides decoded into the sequence of amino acids

23. AP Biology 2005-2006 AUGCGUGUAAAUGCAUGCGCC mRNA mRNA codes for proteins in triplets TACGCACATTTACGTACGCGG DNA AUGCGUGUAAAUGCAUGCGCC mRNA Met Arg Val Asn Ala Cys Ala protein ?

24. AP Biology 2005-2006 The code For ALL life!  strongest support for a common origin for all life Code is redundant  several codons for each amino acid Why is this a good thing? Start codon  AUG  methionine Stop codons  UGA, UAA, UAG

25. AP Biology 2005-2006 How are the codons matched to amino acids? TACGCACATTTACGTACGCGG DNA AUGCGUGUAAAUGCAUGCGCC mRNA amino acid tRNA anti-codon codon 5'3' 5' 3'5' UAC Met GCA Arg CAU Val

26. AP Biology 2005-2006 protein transcription cytoplasm nucleus translation

27. AP Biology 2005-2006 tRNA structure “Clover leaf” structure  anticodon on “clover leaf” end  amino acid attached on 3' end

28. AP Biology 2005-2006 Loading tRNA Aminoacyl tRNA synthetase  enzyme which bonds amino acid to tRNA  endergonic reaction ATP  AMP  energy stored in tRNA-amino acid bond unstable so it can release amino acid at ribosome

29. AP Biology 2005-2006 Ribosomes Facilitate coupling of tRNA anticodon to mRNA codon  organelle or enzyme? Structure  ribosomal RNA (rRNA) & proteins  2 subunits large small

30. AP Biology 2005-2006 Ribosomes P site (peptidyl-tRNA site)  holds tRNA carrying growing polypeptide chain A site (aminoacyl-tRNA site)  holds tRNA carrying next amino acid to be added to chain E site (exit site)  empty tRNA leaves ribosome from exit site

31. AP Biology 2005-2006 Building a polypeptide Initiation  brings together mRNA, ribosome subunits, proteins & initiator tRNA Elongation Termination

32. AP Biology 2005-2006 Elongation: growing a polypeptide

33. AP Biology 2005-2006 Termination: release polypeptide Release factor  “release protein” bonds to A site  bonds water molecule to polypeptide chain Now what happens to the polypeptide?

34. AP Biology 2005-2006 Protein targeting Signal peptide  address label Destinations: secretion nucleus mitochondria chloroplasts cell membrane cytoplasm start of a secretory pathway

35. AP Biology 2005-2006 Can you tell the story? DNA pre-mRNA ribosome tRNA amino acids polypeptide mature mRNA 5' cap polyA tail large subunit small subunit aminoacyl tRNA synthetase EPA 5' 3' RNA polymerase exon intron tRNA

36. AP Biology 2005-2006 Put it all together…

37. AP Biology 2005-2006 Any Questions??